p53 maintains lineage fidelity during lung capillary injury-repair in neonatal hyperoxia
Lisandra Vila Ellis, Jonathan D. Bywaters, Amanda Ceas, Yun Liu, Jennifer M.S. Sucre, Jichao Chen
Lisandra Vila Ellis, Jonathan D. Bywaters, Amanda Ceas, Yun Liu, Jennifer M.S. Sucre, Jichao Chen
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Research Article Development Pulmonology Vascular biology

p53 maintains lineage fidelity during lung capillary injury-repair in neonatal hyperoxia

Abstract

Bronchopulmonary dysplasia (BPD), a prevalent and chronic lung disease affecting premature newborns, results in vascular rarefaction and alveolar simplification. Although the vasculature has been recognized as a main player in this disease, the recently found capillary heterogeneity and cellular dynamics of endothelial subpopulations in BPD remain unclear. Here, we showed that Cap2 cells were damaged during neonatal hyperoxic injury, leading to their replacement by Cap1 cells, which, in turn, significantly declined. Single-cell RNA-Seq identified the activation of numerous p53 target genes in endothelial cells (ECs), including Cdkn1a (p21). While global deletion of p53 resulted in worsened vasculature, EC-specific deletion of p53 reversed the vascular phenotype and improved alveolar simplification during hyperoxia. This recovery was associated with the emergence of a transitional EC state, enriched for oxidative stress response genes and growth factors. Notably, this transitional EC gene signature was conserved in an aberrant capillary population identified in human BPD with pulmonary hypertension, underscoring the biological and clinical relevance of our findings. These results reveal a key role for p53 in maintaining endothelial lineage fidelity during pulmonary capillary repair following hyperoxic injury and highlight the critical contribution of the endothelium to BPD pathogenesis.

Authors

Lisandra Vila Ellis, Jonathan D. Bywaters, Amanda Ceas, Yun Liu, Jennifer M.S. Sucre, Jichao Chen

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Figure 8

scRNA-Seq analysis of neonatal human lungs with BPD+PH reveals an abCap state that shares a transcriptional signature with transitional ECs identified in the hyperoxia mouse model.

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scRNA-Seq analysis of neonatal human lungs with BPD+PH reveals an abCap ...
(A) UMAP of neonatal human lung ECs color coded according to disease status. (B) UMAP of pooled neonatal human lung ECs color coded according to cell population. The subcluster representing an abCap state is only present in BPD+PH. (C) Dot plot of the top 26 genes upregulated in mouse transitional ECs showing their expression in Cap1, Cap2, and abCap cells. Several of these genes are enriched in abCaps. (D) Gene score based on differentially expressed genes found in transitional ECs. This gene signature is upregulated in the abCap cluster in BPD+PH lung ECs compared with ECs in term infants. (E) Transitional EC score for Cap1, Cap2, and abCaps generated from scRNA-Seq data demonstrating that abCaps have a gene signature that resembles transitional ECs more closely than Cap1 or Cap2 cells. abCap, aberrant capillary endothelial cells; BPD, bronchopulmonary dysplasia; PH, pulmonary hypertension.